an integrative framework linking innovations and value chains the case of the kenyan horticulture...
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AN INTEGRATIVE FRAMEWORK LINKING INNOVATIONS AND
VALUE CHAINS
The case of the Kenyan horticulture sector
Aarti Krishnan, University of Manchester, [email protected]
Christopher Foster, University of Sheffield, [email protected]
Introduction
Agricultural value chains and climate change
• Growing demand for more sustainable practices from value chains
• Farmers increasingly effected by weather extremes
=> Climate-based innovation
Literature on climate-based innovationGlobal value chain literature
• Standards/Quality
• Innovation – lead firms, standards-driven, formal innovation (upgrading)
Inclusive innovation
• Climate adaptations based on local knowledge and farmer networks
• Small-scale, frugal innovations
How does the frugality of innovations vary with farmers participating in global and local value chains?
Methodology How do we measure frugal innovation? (World Bank, 2010; Zanello et al., 2015). • Kenya horticulture
(Mango/Avocado)• Survey research on farmer
practices• 300 farmers in 3 regions• ~50/50 GVC and LVC Variables Total
Male 215Female 85 Area: Meru 62Area:Machakos 93Area:Murunga 145 Education: None 12Education: Primary 124Education: Secondary 84Education: High school 56Education: Diploma 16Education: Graduate 8
• Farmer innovation score by value chain• General trends• Frugal GVC farmers• Innovative LVC farmers
• Policy implications – Frugal innovation and GVC, champion LVC farmers
Innovation Types % in Complexity Score Quartilefor GVC Famers
% in Complexity Score Quartilefor LVC Famers
H H-M L-M L H H-M L-M L
Overall 18.1 23.3 22.6 36.1 37.2 33.8 20.0 9.0 Climate Var. 76.8 0.0 0.0 23.2 86.2 0.0 0.0 13.8Climate Extr. 25.8 63.2 0.0 11.0 45.1 51.0 0.0 3.4Conservation 20.0 23.4 49.0 2.6 33.7 26.2 35.9 4.1Climate Adap. 40.9 28.9 16.3 12.3 55.0 25.8 12.0 7.1 Crop Mgm. 26.5 45.8 0.0 27.7 35.9 55.9 0.0 8.3Land Use 45.8 0.0 47.7 6.5 65.5 0.0 32.4 2.1Waste Mgm. 29.0 16.8 48.4 5.8 64.1 15.2 19.3 1.4Water Use 29.0 42.6 0.0 28.4 55.2 26.9 0.0 17.9Sust.Prac. 32.6 26.3 24.0 17.1 55.2 24.5 12.9 7.4
• Overall innovation determinants• Expected trends – skills, education, location, modes of learning; • Unexpected trends – age, alternative livelihoods
Variables Coefficients Std. Err. Z P>z 95% Conf. Interval
Main buyer 0.94 0.29 3.25 0.000 0.38 1.51
Age -0.01 0.01 -1.18 0.240 -0.03 0.01Sex 0.47 0.28 1.68 0.090 -0.08 1.03Alternate activity 2.05 0.42 4.84 0.000 1.22 2.88Education -0.01 0.11 -0.08 0.940 -0.23 0.21Land size 0.02 0.03 0.70 0.490 -0.04 0.08Land ownership -0.33 0.33 -1.02 0.310 -0.97 0.30Farmer group 0.56 0.27 2.04 0.040 0.02 1.09Internet -0.56 0.36 -1.55 0.120 -1.26 0.15Machakos -0.28 0.36 -0.77 0.440 -0.98 0.43Muranga -1.98 0.38 -5.17 0.000 -2.74 -1.23Capacity index 3.62 1.00 3.61 0.000 1.66 5.59Mode of learning - Tacit to mix 2.03 0.80 2.53 0.010 0.46 3.60- Mix to explicit 4.18 0.88 4.74 0.000 2.45 5.92/cut1 2.86 1.09 0.72 5.01/cut2 4.95 1.12 2.77 7.15/cut3 6.81 1.14 4.57 9.03LR chi2(14) =254.07, Log likelihood = -286.80398Prob> chi2 =0, Pseudo R2 =0.307
• Innovation types
• Innovation genres
• Policy implications• Climate adaptation vs sustainable production• How might climate-based innovation be guided
Sustainable production Climate adaptation Quart. land use Quart Waste
MgmtQuart water use
Quart Crop mgmt
Quart climate variability
Quart clim. extreme
Quart conservation
Value chain type 0.584* 0.627** 0.411 0.445 0.616 0.232 0.0144Age -0.00405 -0.00521 -0.0202** 0.00648 0.00729 -0.0148 0.00566Sex 0.342 0.0868 0.0408 0.457 0.143 -0.0234 -0.381Alternate activity in lean season
0.171 0.855** -0.406 -0.332 0.294 0.0653 0.381
Education 0.0793 0.0545 -0.0395 -0.0238 0.106 -0.0315 -0.0599Land size 0.00323 0.00854 -0.00252 0.00989 0.0200 -0.000157 0.00357Land ownership -0.398** -0.104 0.116 -0.660* -0.0556 -0.178 -0.124Part of farmer group 0.468 -0.0139 -0.106 0.653** 0.123 0.447 0.280Internet -0.549 1.005*** 0.0153 -1.039** -0.901* 0.631 -0.472Machakos -0.695** -0.505 -2.010*** -1.240*** -0.246 0.634* 1.515***Muranga -1.852*** 0.893** -2.781*** -3.534*** -0.746* -0.175 1.024***Physical productive index
0.585 0.400 2.474** 4.546*** 0.972 1.364 1.253
2.mode of learning 0.886 16.08 2.042* 2.547** 0.0346 1.348** 1.666***3.mode of learning 2.218** 18.09 3.633*** 2.555** 0.264 2.367*** 2.480***
Results 3
• Modes of learning
• Causality – Feedback effects
• Policy implications• Climate-innovation likely to be
diffuse and adapted• Similarity in determinants –
innovation and value chains
Tacit Tacit and Explicit Explicit 0
102030405060708090
Main mode of learning by value chain
% LVC farmer% GVC farmer
Dependent: VC type
Coef. Std. Err
z P>z 95% confidence interval
Total innovation score
0.083 0.0250 3.32 0.001 0.0340 0.132
Capacity index
1.511 0.5620 2.69 0.007 0.409 2.6127
Land size -0.007 0.005 -1.4 0.162 -0.016 0.0026Education -0.333 0.270 -1.23 0.217 -0.863 0.1964Meru -0.922 0.265 -3.48 0.000 -1.441 -0.403Machakos -0.950 0.241 -3.95 0.000 -1.423 -0.478Age*education
0.0051 0.005 1 0.316 -0.0049 0.0151
Age -0.0155 0.016 -0.98 0.325 -0.0466 0.015Land ownership
-0.258 0.250 -1.03 0.302 -0.7488 0.232
Farmer group
0.817 0.186 4.4 0.000 0.4528 1.181
Md of learning
-Tacit to Mixed
0.2037 0.447 0.45 0.649 -0.67425 1.081
- Mix to explicit
0.9296 0.547 1.7 0.09 -0.14411 2.003
Conclusions
• Integration between innovation and value chains
• Methodology• Innovation types, innovation genres• Score-based scales allow us to explore varying complexity of
innovations
• How might such approaches be used more widely to explore frugal innovation
Conclusions
• Frugality – it’s not just for lower value LVC farmers• A crucial element of GVC and climate adaptation
• LVC and climate innovation • Local market farmers sometimes more innovative
• Innovations types are not all the same• Different genres• How that should effect how they are treated?